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SnO2, TiO2, and Fe2O3) [128]. Other remarkable introductions to conserve the water bodies using PCs as bifurcated units have been pinned up in segments to come. Similar trials have been unfolded in Table 1.3. Photocatalytic action with plausible mechanism is portrayed in Figure 1.5.
Table 1.3 Photocatalyst (PC) as FNMs.
| FNMs as catalyst | Year | Scheme | Process | Irradiation | | Parametric expressions | Probe | Solution evolved | Reusable cycles | Remarks | Ref. |
| 3D-Hem/GH | 2017 | Self-assembly | Visible light | pH (3.82–8.99) | (variable) min. | Rh B | MB | 5 | Contributors ·O2−| π - π interaction | [185] |
| MIL-100(Fe)/PANI | 2020 | Z-Scheme | Ball-milling | White light | pH (2–8) | 120 min | TC (84%) | Cr (VI) (100%) | 5 | Attributors ·OH, ·O2−| π-conjugation | [186] |
| rGO@ZnO | 2020 | Facile synthesis | UV light | pH (5–9) | 300 min | OFX | (99%) | 6 | Reactive (·O2− |·OH), rGO (−4.42 eV) | ZnO (−4.05 eV) | [187] |
| Co-MIL-53-NH-BT | 2020 | Hydrothermal | Step-by-step - assembly | Visible light | > 400 nm | pH (2–8) | 120 min | BPA (99.9%) | OFX (99.8%) | Activators ·OH + H+ + e − → H2O O2−, ·OH, Co3+/Co2+: redox mode | [188] |
| Pt/g-C3N4/Bi2MoO6 | 2019 | Hydrothermal | Visible light | -| 150 min | MB (50%) | VB (2.34V) | CB (-0.86V) Supporters: ·OH, e−, h+, ·O2− | [189] |
| Bi-TiO2 NT/graphene NT | 2017 | Hydrothermal | Visible light | -| 60 min | MB |Herbicide-Dinoseb | 95% |5 | Contributors ·OH | [190] |
| Ni/TiO2 | Ru/TiO2 | 2019 | | Sol-gel | Wet-Impregnation | Sun light | Visible light | pH (natural)| 330 min (IMI) | 480 min (ATP, TMX) | IMI | ATP | TMX | 100% (Insecticides) | Solar (UV) > visible | Degraded products CO2 | H2O | ·OH | [191] |
| ZnO/G/TiO2 (ZGT) | 2016 | Solvothermal | Ultrasonic | pH (9) | 120 min | MB | TBAC-L | TBBU-L TNFW-L | 4 | Contributors: ·O2−, ·OH | π - π interaction | [192] |
| Zn-TCPP/Ag-TiO2 | 2016 | Sol-gel | UV | Visible | -| 30 min | MB | PNP | 4 | Enhancer-Porphyrin | 3.28 eV (bandgap) | [193] |
| Bi2S3/TiO2-Mt | 2018 | Ion exchange | Impregnation | Near UV–Vis-light | pH (11) | 120 min | KP (80%) | - | Langmuir-Hinshelwood | pseudo-1st-order | ·O2− | ·OH | [194] |
| 3D-g-C3N4-NS/TiO2-NF | 2018 | Electrospinning | Thermal redox | Visible light >420nm | - | 120 min | Rh B (~93%) | 3 | Activator ·O2− | pseudo-1st-order | | [195] |
| FeNi 3@SiO2@TiO2 | 2018 | Sol-gel | UV-light | pH (9) | 200 min | TC (100%) | 5 | Contributor ·OH |pseudo-1st-order | | [196] |
| Co3O4/TiO2/GO/amine | 2017 | Sol-gel | Hydrothermal | Solar | Visible light | - | 90 min | | OTC (91%) |CR (91%) |5 | Contributors e · OH, ·O2− CB, h+VB,− | [197] |
| CuInS2/Bi2WO6 | 2019 | Hydrothermal | Visible light | | 120 min | TCH (92.4%) | 4 | Activators: ·O2−, ·OH | Z-scheme | [198] |
| 3D RGO-based hydrogel | Self-assembly | Reduction | UV-VIS | pH (2/3/(acidic) | 120 min | NPX | IBP | DFC | (70-80%) | | Langmuir | Freundlich | π-π interaction | pseudo-2nd-order | [199] |
| CQDs/TCNCs | Hydrothermal | Adsorption-polymerization | Visible light |
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